Molecfit: A general tool for telluric absorption correction. I. Method and application to ESO instruments

TL;DR

Molecfit is a versatile, synthetic-model-based tool for correcting telluric absorption in ground-based astronomical spectra, improving accuracy over previous methods by incorporating detailed atmospheric profiles and instrument effects.

Contribution

It introduces a new method that models Earth's atmospheric transmission using synthetic spectra, applicable to various instruments and observatories, reducing reliance on standard star observations.

Findings

Residuals after correction often below 2% of the continuum

Effective across broad wavelength ranges and spectral resolutions

Outperforms previous correction tools in accuracy

Abstract

Context: The interaction of the light from astronomical objects with the constituents of the Earth's atmosphere leads to the formation of telluric absorption lines in ground-based collected spectra. Correcting for these lines, mostly affecting the red and infrared region of the spectrum, usually relies on observations of specific stars obtained close in time and airmass to the science targets, therefore using precious observing time. Aims: We present molecfit, a tool for correcting for telluric absorption lines based on synthetic modelling of the Earth's atmospheric transmission. Molecfit is versatile and can be used with data obtained with various ground-based telescopes and instruments. Methods: Molecfit combines a publicly available radiative transfer code, a molecular line database, atmospheric profiles, and various kernels to model the instrument line spread function. The atmospheric profiles are created by merging a standard atmospheric profile representative of a given observatory's climate, of local meteorological data, and of dynamically retrieved altitude profiles for temperature, pressure, and humidity. We discuss the various ingredients of the method, its applicability, and its limitations. We also show examples of telluric line correction on spectra obtained with a suite of ESO Very Large Telescope (VLT) instruments. Results: Compared to previous similar tools, molecfit takes the best results for temperature, pressure, and humidity in the atmosphere above the observatory into account. As a result, the standard deviation of the residuals after correction of unsaturated telluric lines is frequently better than 2% of the continuum. Conclusion: Molecfit is able to accurately model and correct for telluric lines over a broad range of wavelengths and spectral resolutions. (Abridged)